Consumable carrier with code reader

ABSTRACT

Provided is a container for transporting a consumable such as a medium on which an image is to be printed. The container includes a support surface and a reading component coupled to the support surface to read a computer-readable code accompanying the consumable. A relay interface is operatively connected to the reading component to receive a signal indicative of the computer-readable code read by the reading component, and communicate with a compatible reader provided to the receiving apparatus to convey information about the computer-readable code read by the reading component to the receiving apparatus. The relay interface can be coupled to the tray at a location remotely located from the reading component and having an orientation that is different from an orientation of the reading component.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No.62/046,246, filed Sep. 5, 2014, which is incorporated in its entiretyherein by reference.

BACKGROUND OF THE INVENTION 1. Field of the Invention

This application relates generally to a tray, container or other carrierof consumables that can be used to identify the consumable therein and,more specifically, to a method and apparatus for relaying informationencoded by a computer-readable code identifying the consumables in thetray, container or other carrier to a reader.

2. Description of Related Art

As an example of a component carrier, a media tray is commonly used tostore printing media such as paper, film, and other types of media onwhich hardcopies of images, text and other printable content arecreated. To load a printer with media, the media tray is inserted into amedia bay from where the printer can retrieve the blank media, ondemand, each time a hardcopy is to be generated. However, users mustmanually identify the specific media in the tray loaded into a printerthat can utilize two or more different types and/or sizes of media.

BRIEF SUMMARY OF THE INVENTION

Accordingly, there is a need in the art for a media tray or othercarrier of consumables that can be utilized to interrogate or read acomputer-readable code accompanying the consumables within the tray toidentify at least one characteristic of the consumables.

According to one aspect, the subject application involves a containerfor transporting a consumable. The container includes a support surfaceon which the consumable to be introduced to a receiving apparatus issupported, and a reading component coupled to the support surface toread a computer-readable code accompanying the consumable supported bythe support surface. A relay interface is operatively connected to thereading component to receive a signal indicative of thecomputer-readable code read by the reading component and communicatewith a compatible reader provided to the receiving apparatus to conveyinformation about the computer-readable code read by the readingcomponent to the receiving apparatus. The relay interface is coupled tothe tray at a location remotely located from the reading component andhaving an orientation that is different from an orientation of thereading component.

According to another aspect, the subject application involves a mediacartridge for storing a consumable medium on which content is to berendered utilizing a hardcopy product apparatus for generating ahardcopy of the content. The media cartridge according to the presentaspect includes a housing comprising support surface on which theconsumable medium rests and a perimeter wall that extends upwardly, froma portion of a periphery of the support surface to define a cavity inwhich the medium is to be stored for consumption by the hardcopyproduction apparatus. A first reading component is coupled to thehousing and includes an interrogation antenna that emits aninterrogation signal in response to being energized to read acomputer-readable code stored by a storage device accompanying theconsumable medium. The interrogation antenna includes a firstorientation relative to the housing. A relay interface is operativelyconnected to communicate with the first reading component and includes arelay antenna in a second orientation relative to the housing that isdifferent from the first orientation of the interrogation antenna. Inresponse to receiving a signal from a compatible reader provided to thehardcopy production apparatus with the relay antenna, the relayinterface transmits an energizing signal to energize the interrogationantenna and initiate reading of the computer-readable code.

The above summary presents a simplified summary in order to provide abasic understanding of some aspects of the systems and/or methodsdiscussed herein. This summary is not an extensive overview of thesystems and/or methods discussed herein. It is not intended to identifykey/critical elements or to delineate the scope of such systems and/ormethods. Its sole purpose is to present some concepts in a simplifiedform as a prelude to the more detailed description that is presentedlater.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWING

The invention may take physical form in certain parts and arrangement ofparts, embodiments of which will be described in detail in thisspecification and illustrated in the accompanying drawings which form apart hereof and wherein:

FIG. 1 shows a top view of an illustrative embodiment of a mediacartridge including a plurality of reading components at differentlocations operatively connected to communicate with a common relayinterface;

FIG. 2 shows a perspective view of the illustrative embodiment of themedia cartridge appearing in FIG. 1;

FIG. 3 shows a perspective view of a media imager comprising a pluralityof vertically-arranged media bays and a contactless, computer-readablecode reader provided adjacent to a lateral side of each of the mediabays;

FIG. 4 shows a schematic representation of an arrangement of an antennarelative to a RFID tag for directly reading data stored by the RFID tag;

FIG. 5 shows a schematic representation of an arrangement of an antennarelative to a RFID tag for reading data and/or updating data stored bythe RFID tag utilizing a relay interface having an orientation otherthan parallel to the RFID tag for indirectly reading and/or updating thedata via the relay interface;

FIG. 6 shows a perspective view of an alternate embodiment of a mediacartridge including a single interrogation antenna configured toestablish a plurality of reading regions at different locations along abottom surface of a media cartridge operatively connected to communicatewith a common relay interface; and

FIG. 7 shows a top view of an alternate embodiment of a media cartridgeincluding a single interrogation antenna configured to establish aplurality of reading regions at different locations along a bottomsurface of a media cartridge operatively connected to communicate with acommon relay interface.

DETAILED DESCRIPTION OF THE INVENTION

Certain terminology is used herein for convenience only and is not to betaken as a limitation on the present invention. Relative language usedherein is best understood with reference to the drawings, in which likenumerals are used to identify like or similar items. Further, in thedrawings, certain features may be shown in somewhat schematic form.

It is also to be noted that the phrase “at least one of”, if usedherein, followed by a plurality of members herein means one of themembers, or a combination of more than one of the members. For example,the phrase “at least one of a first widget and a second widget” means inthe present application: the first widget, the second widget, or thefirst widget and the second widget. Likewise, “at least one of a firstwidget, a second widget and a third widget” means in the presentapplication: the first widget, the second widget, the third widget, thefirst widget and the second widget, the first widget and the thirdwidget, the second widget and the third widget, or the first widget andthe second widget and the third widget.

FIG. 1 shows a top view of a media cartridge 10 as an example of acontainer for transporting a consumable such as film or paper, forexample. Although any container that stores a consumable item is withinthe scope of the present disclosure, for the sake of brevity thecontainer will be described with reference to the media cartridge 10storing film to be supplied to a medical imager 32 (FIG. 3) forgenerating hardcopy images on film (e.g., x-ray images, CT scan images,other medical images for diagnostic purposes, etc . . . ). An example ofsuch a medical imager 32 is the Horizon® multi-media imager fromCodonics, Inc.

As shown in FIG. 1, the media cartridge 10 forms a housing that includesa support surface 12 on which the film or other consumable medium to beintroduced to the medical imager 32, an office printer, or otherreceiving apparatus that consumes media is to be supported. The supportsurface 12 can be substantially planar, optionally including one or moreapertures 14 granting access to an interior of the media cartridge 10while the media cartridge 10 is in use. A perimeter wall 16 extendsupwardly from the support surface 12, along a portion (e.g., entirelyabout; along at least some; or most, but less than all) of the peripheryof the support surface 12 to define a cavity-like recess in which theconsumable medium is to be placed, and from where it can be retrieved bythe medical imager 32. The peripheral wall forms an angle of ten (10°)degrees relative to the support surface 12, but can be at least fortyfive (45°) degrees or approximately ninety (90°) degrees relative to thesupport surface 12, without departing from the scope of the presentdisclosure.

The media cartridge 10 also includes at least one reading component 18coupled to the housing at a location such as a portion of the supportsurface 12. The reading component 18 can be a RFID reader terminal, forexample. For such embodiments, the reading component 18 includes anelectronic circuit 20 that controls delivery of an alternatinginterrogation signal to an interrogation antenna 22 in the form of aloop of an electrically-conductive material such as copper to generatean alternating electromagnetic field that is used to excite a compatibleantenna provided with the media in the cartridge 10, and receipt of acomputer-readable code emitted by the corresponding antenna excited bythe electromagnetic field in return. More specifically, this fieldgenerated by the interrogation antenna can be used to inductivelygenerate a current through a compatible antenna provided to a RFID tagaccompanying the film or other print media resting on the supportsurface 12 and storing the computer-readable code. The RFID tag canoptionally be adhered or otherwise coupled to an optional liner made ofpaper or other suitable material that separates the film from thesupport surface 12, placed between the film or other media from thesupport surface 12, or otherwise inserted into the cartridge 10 alongwith the film or other media. Such a current inductively generated inthe antenna of the RFID tag accompanying the film in response to beingexposed to the field generated by the interrogation antenna 22 issufficient to temporarily energize a circuit including acomputer-readable memory (e.g., solid state memory) provided to the RFIDtag accompanying the film. Once energized, this circuit transmits thecomputer-readable code identifying the film stored in the memory bymodulating the current flowing through the antenna provided to the RFIDtag to emit a suitable response signal, or otherwise transmitting thecode as a signal through the antenna of the RFID tag, which alsogenerates a field that is sensed by the interrogation antenna 22provided to the reading component 18, thereby allowing the readingcomponent to “read” the computer-readable code from the RFID tagaccompanying the film.

Since the reader component 18 lacks an onboard, robust power supply andcommunication circuitry that would facilitate active communications witha RFID reader 36 provided to a lateral side of the medical imager 32 asdiscussed below with reference to FIGS. 3 and 4, the RFID reader 36 ofthe medical imager 32 does not communicate directly with the readingcomponent 18 wirelessly (e.g., inductively). Further, the medical imager32 shown in FIG. 3 can receive a plurality of different media cartridges10 in a vertically-stacked arrangement, each storing a different imagingmedium accompanied by RFID tags storing different computer-readablecodes identifying those media. The RFID reader 36 of the imager 32 doesnot generate a field of sufficient strength to interrogate the RFID tagsaccompanying the different media cartridges 10 directly because such awide-range field would interrogate more than one RFID tag, and would notdifferentiate the data sent in return, which could include multiples ofthe same computer-readable code. And since the media cartridge(s) 10is/are removable, there are no hardwired connections between the readingcomponent 18 of each media cartridge 18 and the RFID reader provided tothe medical imager 32. To allow for the use of a relatively low-powerinterrogation signal to limit the range of interrogation to a specificmedia cartridge 10 (e.g., and not interrogate the RFID tag provided tomore than one cartridge), the media cartridge 10 can also include arelay interface 24, also shown in FIG. 2.

As shown, the reading component 18 is coupled to the support surface 12inward of the of the perimeter wall 16 extending along the portion ofthe periphery of the support surface, and the relay antenna is coupledto the perimeter wall 16, at the periphery of the support surface 12.The reading component 18 can even be arranged adjacent to a centralregion of the support surface 12. The relay interface 24 can behardwired with wires 26 made of an electrically-conductive materialoptionally embedded in the support surface 12 (e.g., disposed to runwithin longitudinal channels formed in the support surface 12), orotherwise operatively connected to communicate with the readingcomponent 18. Like the reading component 18, the relay interface 24includes a relay antenna 28 in an orientation relative to a portion ofthe housing such as the support surface 12, for example, that isdifferent from the orientation of the interrogation antenna 22 relativeto that same portion (e.g., the support surface 12). In this manner, theinterrogation antenna 22 of the reading component 18 can be arranged tobe substantially parallel with a major plane of the consumable mediumsupported by the support surface 12, allowing the interrogation antenna22 to be substantially parallel with the antenna of the RFID tagaccompanying the print medium in the media cartridge 10. The relayantenna 28 can thus be arranged approximately orthogonal to theinterrogation antenna 22, yet communication between the relay component24 and the RFID reader provided to the medical imager 32 through RFcommunication can be established.

For the medical imager 32 appearing in FIG. 3, space considerationsbetween a plurality of vertically-aligned media bays 34 provided to theimager 32 may prevent a RFID reader 36 from being positioned on themedical imager 32 adjacent to, and parallel with the support surface 12of the media cartridge 10. Ideally, and as schematically illustrated inFIG. 4, a RFID reader 36 positioned as such would be parallel with thesupport surface 12, and emit an excitation field 38 extending generallyperpendicular to, or at least outwardly from the plane in which a coilRFID antenna 40 of the RFID reader 36 is arranged. The excitation field38 for such an arrangement would induce a current through an antennaprovided to the RFID tag 46 accompanying the film or other print mediaon the support surface 12, thereby temporarily energizing the circuitryof that RFID tag 46 to emit a signal indicative of the type of filmand/or other quality of the media contained by the media cartridge 10.However, due to the limited space between the media bays 34 shown inFIG. 3, arranging the RFID reader 36 in this manner between the mediabays 34 may not be practical, or even possible.

Instead, the media cartridge 10 discussed herein allows for theinstallation of the RFID reader 36, or other computer-readable codereader, adjacent to a lateral side 42 of a receiving bay 34 where themedia cartridge(s) 10 is/are to be inserted, as shown in FIG. 3. Themedical imager 32 can optionally include a sensor that detects when amedia cartridge 10 is inserted. In response to detection insertion ofthe media cartridge 10, the RFID reader 36 can be energized using powersupplied to the medical imager 32 through a conventional AC mains walloutlet to conduct a current through the antenna 40 and generate thefield 38, as shown in FIG. 5. The field 38 emitted by the RFID reader 36provided to the medical imager 32 induces a current through the relayantenna 28 of the relay interface 24 which, in turn, transmits anenergizing signal that is conducted by the wires 26 to the readingcomponent 18 to energize the interrogation antenna 22, which is arrangedsubstantially orthogonal to the relay antenna 28 on the media cartridge10 according to the present embodiment. In response to being energized,the interrogation antenna 22 emits a field 44 similar to the field 38emitted in response to energizing the antenna 40 to initiate reading ofthe computer-readable code stored by the RFID tag 46 accompanying theprint medium stored by the media cartridge 10. This field emitted by theinterrogation antenna 22 induces a current in the antenna provided tothe RFID tag 46 accompanying the media contained by the media cartridge10, which can be used to temporarily energize an onboard circuitprovided to RFID tag 46. Once energized, the circuit provided to theRFID tag 46 can read and/or update data stored by a computer memoryprovided to the RFID tag 46. If data is read, this read data is returnedas a modulated version of the field 44, which is sensed by theinterrogation antenna 22 and, in turn, conducted back to the relayinterface 24 via the wires 26, from where it can be wirelesslytransmitted as a modulated field 38 back to the antenna 40 provided tothe RFID reader 36 on the medical imager 32.

Examples of the data that can be read from and/or stored to the RFID tag46 utilizing the present media cartridge include, but are not limited toat least one of: a type of media contained in the media cartridge 10, aquantity of media contained in the media cartridge, a source (e.g., amanufacturer) of the media contained in the media cartridge, and aquality or any other specification relating to the media contained inthe media cartridge 10.

Due to the different orientation of the relay antenna 28 relative to theinterrogation antenna 22, the present media cartridge 10 provides addedflexibility for the location of the RFID reader 36 provided to themedical imager 10.

According to alternate embodiments, the support surface 12 can alsoinclude a second reading component 30 operatively connected to the relayinterface 24 via wires 26. The second reading component 30 can becoupled to the support surface 12 at a second location inward of theperimeter wall 16 that is different from the location of the readingcomponent 18. Thus, different media may be accompanied by RFID tags atdifferent locations. To render the media cartridge 10 compatible withsuch different media, a reading component can be provided at eachlocation where the RFID tag accompanying the different media is expectedto be positioned.

Each of the embodiments described above involves the use of a passivesystem to read a computer-readable code accompanying a medium containedby the cartridge 10 to allow the imager 32 or other hardcopy productiondevice to identify that medium. As such, the cartridge 10 lacked anonboard power supply such as a battery or interface that electricallyconnects the cartridge 10 to the imager 32. However, according toalternate embodiments, the cartridge 10 can include a battery providedto the relay interface 24, the reading component 18, or other component;or include an electrical connector that establishes electricalcontinuity between an external power source (e.g., a power supplyprovided to the imager 32) and the relay interface 24 and/or readingcomponent 18 to create an “active” repeating system. Such active systemsinclude a relay interface 24 that communicates wirelessly with the RFIDreader 36, but can actively process and facilitate with the RFID tagaccompanying the medium in the cartridge 10 using the available powersupply, and without being energized by current induced by the RFIDreader 36.

An alternate embodiment of a media cartridge 10 is shown in FIG. 6. Theembodiments discussed above utilize one interrogation antenna 22 tocommunicate with a RFID tag arranged at a fixed location correspondingto that interrogation antenna 22. A plurality of distinct interrogationantennas 22 can be arranged along the support surface 12 at differentlocations as shown in FIG. 1 to support communications with RFID tags ata plurality of respective locations above those interrogation antennas22. As shown in FIG. 6, however, the cartridge 10 includes a single,continuous interrogation antenna 22 configured to extend about, andestablish a plurality of reading regions 50 at different locations alonga support surface 12 of the media cartridge 10. Thus, the plurality ofdifferent reading regions 50 established by the interrogation antenna 22are operatively connected to communicate with a common relay interface24.

Each reading region 50 can correspond to a location defined by a “loop”formed by the interrogation antenna 22 vertically below where the RFIDtag is expected to be arranged with the medium in the cartridge 10 to beread. For the embodiment in FIG. 6, there are two reading regions 50arranged to read the computer-readable code from an RFID tag arranged inthe cartridge 10 vertically above those reading regions 10, or withinreasonably-close proximity thereof to allow for the interrogation of theRFID tag described herein to be performed. Although referred to as beingdefined by “loops”, the reading regions 50 do not necessarily have to beperfectly circular in shape or be fully enclosed, but merely have toform a continuous periphery that defines a majority of a completeenclosure. For the example shown in FIG. 6, each loop is somewhatrectangular in shape when viewed from directly above the reading regions50, and form approximately three of four sides (¾) of an enclosedrectangle, with openings leading to an intervening low-intensity region52 separating the reading regions 50.

Separating at least two reading regions 50 can be a low-intensity region52 where the spacing separating regions of the conductive materialforming the interrogation antenna 22 is less than the spacing of thatmaterial forming the reading regions 50 separated by the low-intensityregion 52. This material can be, for example, a co-axial cable, acontrolled impedance PCB strip line, twisted pair wires, or any otherconnection system that effectively transmits energy and data between therelay antenna 28 and the interrogation antenna 22. For the illustrativeembodiment shown in FIG. 6, the distance D1 separating the materialforming the low-intensity region 52 is less than the distance D2 betweenthe antenna material on opposite sides of a “loop” to establish thereading region 50 on either side of the low-intensity region 52.

The interrogation antenna material is configured in to low-intensityregions 52 to minimize magnetic field flux. This is achieved by pinchingdown opposing polarities of the target antenna into tightly-coupleddifferential pair traces, for example. The result of this antennashaping is to maximize field flux and energy density in the regionsvertically above the reading regions 50 where the RFID tag identifyingthe medium in the cartridge 10 are expected to be located and minimizeenergy density in other regions where the RFID tags are not expected tobe located. Due to the low-energy levels of the current induced by theRFID reader 36, the relatively-large loops of the interrogation antenna22 achieve suitable energy transfer and communication signal strength toread the computer-readable code from the RFID tag identifying the mediumin the cartridge 10. In contrast, the low-intensity regions 52 do notachieve suitable energy transfer and communication signal strength toread the computer-readable code from the RFID tag.

Another embodiment of the interrogation antenna 22 is shown in FIG. 7.According to the present embedment, a single interrogation antenna 22 isconfigured to establish a plurality (three in FIG. 7) of reading regions50 at different locations along a support surface 12 of a mediacartridge 10 operatively connected to communicate with a common relayinterface 24. The distances shown in FIG. 7 are expressed in inches, andare provided only as an example of the different dimensions of thereading regions 50 and the relatively-low-intensity regions 52separating those reading regions 50 from each other. The dimensions arenot to be considered to be the only suitable dimensions, or limiting thescope of the present disclosure, as different dimensions also fallwithin the scope of the present application. The dimensions appearing inFIG. 7 are merely illustrative, and are provided simply to highlight theconcept that the reading regions 50 generally have greater separationbetween the material forming the interrogation antenna 22 in thoseregions than the material forming the interrogation antenna 22 in thelow-intensity regions 52 between the reading regions 50.

Each of the relay antenna 28 and the interrogation antennas 22 canoptionally be connected to the relay interface 24 using electronics(referred to generally at 54 in FIG. 7) to match the impedance of thoseantennas to the impedance of the relay interface 24. This matching canbe performed using a process referred to as “tuning” or “impedancematching” that is widely known in the art. The purpose of tuning is tomaximize power transfer from one antenna to the other, maximize signalintegrity of the system, and minimize signal reflections at theinterfaces between the relay interface 24 and the antennas 28, 22. Thetuning can be performed once the entire system positioned in the finalorientation in the product or environment in which the system isexpected to operate (e.g., once the cartridge 10 has been fully insertedinto the imager 32 and is in position for use to produce hardcopies ontothe medium in the cartridge 10). This way, any effects of surroundingmetal or other objects will be taken into account in the final tuningvalues.

The relay interface 24 or other portion of the present system can alsoinclude an amplifier, repeater, or other device (generally referred toat 56 in FIG. 7) to repeat the signal and/or amplify the powertransmitted between the relay antenna 28 and the interrogation antenna22. This device 56 would typically be powered by an energy sourceindependent of the relay antenna 28 (e.g., powered by a source ofelectric energy such as a battery, or power supply provided to theimager 32, for example, that does not consume the current induced in therelay antenna 28).

Illustrative embodiments have been described, hereinabove. It will beapparent to those skilled in the art that the above devices and methodsmay incorporate changes and modifications without departing from thegeneral scope of this invention. It is intended to include all suchmodifications and alterations within the scope of the present invention.Furthermore, to the extent that the term “includes” is used in eitherthe detailed description or the claims, such term is intended to beinclusive in a manner similar to the term “comprising” as “comprising”is interpreted when employed as a transitional word in a claim.

What is claimed is:
 1. A container for transporting a consumable, thecontainer comprising: a support surface on which the consumable to beintroduced to a receiving apparatus is supported; a reading componentcoupled to the support surface to read a computer-readable codeaccompanying the consumable supported by the support surface; and arelay interface operatively connected to the reading component toreceive a signal indicative of the computer-readable code read by thereading component and communicate with a compatible reader provided tothe receiving apparatus to convey information about thecomputer-readable code read by the reading component to the receivingapparatus, the relay interface being coupled to the tray at a locationremotely located from the reading component and having an orientationthat is different from an orientation of the reading component.
 2. Thecontainer of claim 1 further comprising a perimeter wall oriented at anangle greater than ten (10°) degrees relative to the support surface,wherein the relay interface is supported adjacent to the perimeter walland the reading component is supported adjacent to the support surface.3. The container of claim 2, wherein: the reading component comprises afirst antenna comprising a first coil wound in a plane that issubstantially parallel with the support surface and a coil of aconsumable antenna storing the computer-readable code accompanying theconsumable, and the relay interface comprises a second antennacomprising a second coil wound in a plane that is substantially parallelwith the perimeter wall.
 4. The container of claim 2, wherein the angleis greater than or equal to forty five (45°) degrees relative to thesupport surface, and the perimeter wall extends longitudinally along aperiphery of the tray.
 5. The container of claim 2, wherein the angle isapproximately ninety (90°) degrees relative to the support surface, andthe perimeter wall extends longitudinally along a periphery of the tray.6. The container of claim 1 further comprising a hardwired connectionextending between the reading component and the relay interface.
 7. Thecontainer of claim 1 further comprising a second reading componentoperatively connected to the relay interface and coupled to the supportsurface at a second location that is different from a location of thereading component, wherein the reading component and the second readingcomponent are arranged along the support surface to read differentcomputer-readable codes at different positions relative to theconsumable provided to the container.
 8. The container of claim 1,wherein the relay interface comprises an antenna through which a currentis inductively generated by an alternating field emitted by thecompatible reader provided to the receiving apparatus, the relayinterface being adapted to transmit a signal to be received by thereading component to initiate reading of the computer-readable code inresponse to the current.
 9. The container of claim 8, wherein thereading component comprises a radio-frequency antenna that transmits aninterrogation signal in response to receiving the signal transmitted bythe relay interface to energize a RFID antenna storing thecomputer-readable code provided to the consumable.
 10. A media cartridgefor storing a consumable medium on which content is to be renderedutilizing a hardcopy product apparatus for generating a hardcopy of thecontent, the media cartridge comprising: a housing comprising supportsurface on which the consumable medium rests and a perimeter wall thatextends upwardly, from a portion of a periphery of the support surfaceto define a cavity in which the medium is to be stored for consumptionby the hardcopy production apparatus; a first reading component coupledto the housing and comprising an interrogation antenna that emits aninterrogation signal in response to being energized to read acomputer-readable code stored by a storage device accompanying theconsumable medium, the interrogation antenna comprising a firstorientation relative to the housing; and a relay interface operativelyconnected to communicate with the first reading component and comprisinga relay antenna in a second orientation relative to the housing that isdifferent from the first orientation of the interrogation antenna,wherein, in response to receiving a signal from a compatible readerprovided to the hardcopy production apparatus with the relay antenna,the relay interface transmits an energizing signal to energize theinterrogation antenna and initiate reading of the computer-readablecode.
 11. The media cartridge of claim 10, wherein the interrogationantenna is coupled to the support surface, inward of the perimeter wallextending along the portion of the periphery of the support surface, andthe relay antenna is coupled to the perimeter wall, at the periphery ofthe support surface.
 12. The media cartridge of claim 10, wherein theinterrogation antenna is arranged to be substantially parallel with amajor plane of the consumable medium supported by the support surface,and the relay antenna is approximately orthogonal to the interrogationantenna.
 13. The media cartridge of claim 10 further comprising a secondreading component operatively connected to the relay interface andcoupled to the support surface at a second location inward of theperimeter wall that is different from a location of the first readingcomponent.
 14. The media cartridge of claim 13 further comprising ahardwired connection extending between each of the first and secondreading components and the relay interface.